Dynamic multi-point access network

ABSTRACT

A router is operatively coupled to a plurality of local computers and has one or more connections to a remote computer network for managing one or more data routes between the local computers and the remote computer network. In providing dynamic access to the remote computer network by any of the local computers, one or more of the connection(s) of the router to the remote computer network includes one or more wireless connections independent of the router between the local computers and the remote computer network.

TECHNICAL FIELD OF THE INVENTION

The present invention generally relates to routers. The presentinvention specifically relates to creating an optimal aggregatebandwidth by a router from multiple broadband sources within a localcomputer network.

BACKGROUND OF THE INVENTION

A router is a device that forwards data packets between computernetworks, and the amount of information per unit of time that can beexchanged between the router and another device is generally known asbandwidth. For example, in the context of a home or a business, a routermay be utilized to forward data packets between a local computer and theInternet at a specified broadband transmission.

Multiple bandwidth sources of varying types may exist within a localcomputer network at any given time. In particular, a mobile phone ormobile data card in a computer may be added ad hoc to the local computernetwork and the router can aggregate all of its connected devices, wiredand wireless, into a single bandwidth route to a remote computernetwork. The routing industry is striving to provide new and uniquetechniques for optimizing such aggregate bandwidth.

SUMMARY OF THE INVENTION

In one disclosed embodiment, a local computer network employing aplurality of local computers, and a router having one or moreconnections to a remote computer network is disclosed. Theseconnection(s) provide for one or more data routes between the localcomputers and the remote computer network that are managed by therouter. In providing for a dynamic access to the remote computer networkby any of the local computers, one or more of the connection(s) of therouter to the remote computer network includes one or more wirelessconnections between the local computers and the remote computer networkthat is independent of the router.

In another disclosed embodiment, a method of operating a router within alocal computer network is disclosed. The method involves operativelycoupling the router to a plurality of local computers, and connectingthe router to a remote computer network for managing one or more dataroutes between the local computers and the remote computer network. Inproviding for a dynamic access to the remote computer network by any ofthe local computers, one of the connections of the router to the remotecomputer network includes one or more wireless connections between thelocal computers and the remote computer network that is independent ofthe router.

The foregoing embodiments and other embodiments of the present inventionas well as various features and advantages of the present invention willbecome further apparent from the following detailed description ofvarious embodiments of the present invention read in conjunction withthe accompanying drawings. The detailed description and drawings aremerely illustrative of the present invention rather than limiting, thescope of the present invention being defined by the appended claims andequivalents thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a block diagram of an exemplary embodiment of anetwork environment in accordance with the present invention;

FIG. 2 illustrates a flowchart representative of an aggregate bandwidthmethod of the present invention;

FIG. 3 illustrates a schematic diagram of a first exemplary embodimentof the network environment shown in FIG. 1 in accordance with thepresent invention; and

FIG. 4 illustrates a schematic diagram of a second exemplary embodimentof the network environment shown in FIG. 1 in accordance with thepresent invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

For the purposes of promoting an understanding of the principles of theinvention, reference will now be made to the embodiments illustrated inthe drawings and specific language will be used to describe the same. Itwill nevertheless be understood that no limitation of the scope of theinvention is thereby intended, and alterations and modifications in theillustrated devices and methods, and further applications of theprinciples of the invention as illustrated therein are hereincontemplated as would normally occur to one skilled in the art to whichthe invention relates.

A router according to the presently disclosed embodiments incorporatescommon router features (e.g., routing tables, rules, protocols,firewalls, port forwarding, etc.) with a novel routing scheme involvingdynamic access by a local computer network (e.g., a local area networkor a wide area network) of which the router is a part to a remotecomputer network (e.g., a local area network or a wide area network) towhich the router is remotely connected. In particular, the routercombines all the available bandwidth from multiple connections to theremote computer network and allows access by the local computer networkto the remote computer network on a selective allocation of theaggregate bandwidth. The dynamic access to the remote computer networkis derived from the router using wireless connections of the localcomputer network independent of the router to the remote computernetwork. The following description of an exemplary router 10 of thepresent invention as shown in FIG. 1 and an exemplary routing method 40of the present invention as shown in FIG. 2 will facilitate furtherunderstanding of the present invention.

Specifically, FIG. 1 illustrates router 10 having a W number of physicalports 13 for wired connections to a W number of computers 20 (e.g.,desktops or servers), where W≧1, and an X number of wireless ports 14for wireless connections to an X number of computers 21 (e.g., laptops),where X≧1. Alternatively, a portion or all of the wired and wirelessconnections may be to another computer network (e.g., an Ethernet).Additionally, router 10 has a Y number of physical ports 15 for wiredconnections to a Y number of computers 22 (e.g., desktops or servers),where Y≧1, and a Z number of wireless ports 16 for wireless connectionsto a Z number of computers 23 (e.g., laptops), where Z≧1.

In operation, router 10 implements a control unit 11 structurallyconfigured to implement common router features (e.g., routing tables,rules, protocols, firewalls, port forwarding, etc.). A bandwidthmanagement module 12 is incorporated in router 10, either within controlunit 11 or working in conjunction with control unit 11, to executeflowchart 40 (FIG. 2) for the dynamic access between local computers20-23 and remote computer network 30. Additionally, a bandwidthmanagement module 24 is incorporated in each computer 23 to facilitatebandwidth management module 12 in executing flowchart 40.

Specifically, as shown in FIG. 2, module 12 during a stage S41 offlowchart 40 determines if a new connection between router 10 and remotecomputer network 30 has been established, if an existing connectionbetween router 10 and remote computer network 30 has been terminated orif a bandwidth availability status of an existing connection betweenrouter 10 and remote computer network 30 has changed (collectively a“bandwidth event”). For the dynamic access scheme of the presentinvention, such connections include independent wireless connectionsbetween computers 22, 23 and remote computer network 30 as shown in FIG.1 via any type of wireless network (e.g., a 3G network, a WiFi networkand a WiMax network). In particular, module 12 communicates with abandwidth module 24 incorporated within computers 22, 23 to determinethe available bandwidth between the computers 22, 23 and the remotecomputer network 30 as well as the access parameters required forallowing module 12 to exchange data packets with remote computer network30 via computers 23.

Upon making a determination of a bandwidth event, module 12 proceeds toa stage S42 of flowchart 40 to determine an aggregate bandwidth of allof the data routes between local computers 20-23 and remote computernetwork 30 (in some embodiments, module 12 aggregates multiple, but notall, available data routes). The aggregate bandwidth increases for abandwidth event where a new connection between router 10 and remotecomputer network 30 has been established (e.g., a new wirelessconnection between a local computer 23 and remote compute network 30),and conversely decreases for a bandwidth event where an existingconnection between router 10 and remote computer network 30 has beenterminated (e.g., a disconnection of a wireless connection between alocal computer 23 and remote computer network 30). Furthermore, theaggregate bandwidth is adjusted for a bandwidth event where thebandwidth availability of a connection between router 10 and remotecomputer network 30 has changed. This bandwidth aggregation of stage S42enables computers 20-23 to operate as if they were all connected to alarge bandwidth pipe while being unaware of the multiple data routeswith remote computer network 30. As such, computers 23 may be coupledand decoupled to router 10 without any impact to the local computernetwork, because module 12 dynamically adjusts the size of the availablebandwidth as needed.

Upon determining an aggregate bandwidth, module 12 proceeds to a stageS43 of flowchart 40 to allocate the aggregate bandwidth to localcomputers 20-23 as needed. Generally, module 12 ascertains whichconnections, particularly wireless connections, should be utilized in anexchange of data packets between local computers 20-23 and remotecomputer network 30.

In one allocation mode, module 12 executes a load balancing over aportion, if not all, of the available data routes. In another allocationmode, module 12 segregates the aggregate bandwidth into two or moreindependent bandwidth routes for the selective allocation of one of thebandwidth routes to each data exchange between local computers 20-23 andremote computer network 30. The segregation of the aggregate bandwidthby module 12 is based on one or more predetermined routing parametersthat provide for an intelligent use of the aggregate bandwidth.Furthermore, a load balancing technique may be implemented for eachbandwidth route including multiple connections to remote computernetwork 30. A more detailed explanation of stage S41 will now beprovided herein with reference to FIG. 3 and FIG. 4.

Specifically, FIG. 3 illustrates a router 50 (having the samearchitecture as router 10) having wired connections to desktops 60 and61, a laptop 65, and servers 66 and 67, and wireless connections tolaptops 62-64. In an alternative embodiment, FIG. 4 illustrates servers66-68 having a wired connection to a router 51, which has a routerconnection to router 50. Additionally, FIGS. 3 and 4 illustrate a wiredconnection to Internet 80 via an Internet service provider 70 having abandwidth A, a wireless connection by laptop 62 to Internet 80 via anAirCard of laptop 62 and a wireless network 71 (e.g., a 3G network)having a bandwidth B, a wireless connection by laptop 63 to Internet 80via an AirCard of laptop 63 and a wireless network 72 (e.g., a WiFinetwork) having a bandwidth C, and a wireless connection to Internet 80via an AirCard of laptop 65 and wireless network 73 (e.g., a WiMaxnetwork) having a bandwidth D. The connections have an aggregatebandwidth A-D. Computers 60, 61, 64, 66 and 67 have no direct connectionto internet 80. In one example, bandwidth B is 10 Mbps, bandwidth C is 2Mbps and bandwidth D is 5 Mbps for a total bandwidth of 18 Mbps for thewireless connections that may shared along with wired bandwidth A by allof the local computers coupled to the router.

In order to accomplish this sharing of bandwidth by the local computerscoupled to router 50, each of the computers having an externalconnection to internet 80 are provided with software that enables themto share with router 50 information about the currently-availablebandwidth and access parameters that the router 50 will use to aggregatethe total available bandwidth and make it available to all of thecomputers coupled to router 50. This bandwidth is made available as asingle connection, such that the devices in the network only need to beaware of the single connection to internet 80 provided by the router 50,and would not need to be aware of the total number of actual connectionsto internet 80, which number can be dynamically changing while any ofthe network devices are communicating with internet 80.

Referring to FIGS. 3 and 4, for load balancing purposes, module 12 willutilize the aggregate bandwidth A-D as needed to exchange data packetsbetween the local computers and Internet 80. The dynamic nature oflaptops 62, 63 and 65 being connected or disconnected from router 50 andInternet 80 at any given moment in time as well as the dynamic nature ofadditional laptops being connected to or disconnected from router 50 andInternet 80 at any given moment in time is constantly being monitored byrouter 50 to ensure a complete and accurate data exchange between router50 and Internet 80.

Still referring to FIGS. 3 and 4, for bandwidth segregation purposes,one routing parameter that may be utilized by module 12 in segregatingaggregate bandwidth A-D may be the type of connection between router 50and Internet 80. For example, module 12 may segregate the aggregatebandwidth A-D into a wired bandwidth route A for the wired connectionbetween router 50 and Internet 80, and a wireless bandwidth route B-Dfor the wireless connections between router 50 and Internet 80. A loadbalancing technique may be implemented for wireless bandwidth route B-D.

Another routing parameter that may be utilized by module 12 insegregating aggregate bandwidth A-D may be the type of connectionbetween router 50 and the local computers. For example, as shown in FIG.3, module 12 may segregate the aggregate bandwidth A-D into a wiredbandwidth route A for the wired connections between router 50 andcomputers 60, 61 and 65-67, and a wireless bandwidth route B-D for thewireless connections between router 50 and computers 62-64. Also byexample, as shown in FIG. 4, module 12 may segregate the aggregatebandwidth A-D into a wired bandwidth route A for the wired connectionsbetween router 50 and computers 60, 61 and 65 and router 51, and awireless bandwidth route B-D for the wireless connections between router50 and computers 62-64.

Another routing parameter that may be utilized by module 12 insegregating aggregate bandwidth A-D may be the mode of connectionbetween router 50 and the computers. For example, as shown in FIG. 4,module 12 may segregate the aggregate bandwidth A-D into a directbandwidth route A for the direct connections between router 50 andcomputers 60-65, and a switch bandwidth route B-D for the connectionsbetween router 50 and router 51.

Another routing parameter that may be utilized by module 12 insegregating aggregate bandwidth A-D may be the latency of the dataroutes. For example, module 12 may segregate the aggregate bandwidth A-Dinto a low latency bandwidth route A for each data exchange of video,audio and/or images between router 50 and Internet 80, and a highlatency bandwidth route B-D for each data exchange of text and/ordatabase data between router 50 and Internet 80.

Another routing parameter that may be utilized by module 12 insegregating aggregate bandwidth A-D may be the directional flow of databetween router 50 and Internet 80. For example, module 12 may segregatethe aggregate bandwidth A-D into an upstream bandwidth route A forupstream data exchange from router 50 to Internet 80, and a downstreambandwidth route B-D for each downstream data exchange from Internet 80to router 50.

Another routing parameter that may be utilized by module 12 insegregating aggregate bandwidth A-D may be the desired security level ofthe data exchange between router 50 and Internet 80. For example, module12 may segregate the aggregate bandwidth A-D into a bandwidth route A-Bfor secure data exchange between router 50 and Internet 80, and abandwidth route C-D for each unsecure data exchange between router 50and Internet 80.

Another routing parameter that may be utilized by module 12 insegregating aggregate bandwidth A-D may be the security level of eachconnection between router 50 and Internet 80. For example, module 12 maysegregate the aggregate bandwidth A-D into a bandwidth route A-B forsecure connections between router 50 and Internet 80, and a bandwidthroute C-D for unsecure connections between router 50 and Internet 80.

Referring again to FIG. 2, module 12 will continually execute stagesS41-43 of flowchart 40 until such time router 10/50 is powered off. Inpractice, module 12 may be implemented in hardware, firmware and/orsoftware as would be appreciated by those having ordinary skill in theart. Furthermore, module 12 may provide an administrator control panelto enable a customization of routing and access restrictions. Forexample, the control panel can enable an administrator to define whichlocal computers may or may not functions as access points to the networkor, alternatively, to allow any local computer to function as an accesspoint. In cases where specific access devices are identified, thecontrol panel can connect to the wireless service provider account totrack the overall usage (both while connected and unconnected to therouter 10/50) of each local computer and to set rules to control theamount of bandwidth that is consumed by the local computer network basedon the wireless rate plan and/or other business rules. The control panelcan additionally define routing requirements for specific types of datatraffic. For example, the control panel may specify that encrypted datatraffic will only be routed over secure connections, etc. The controlpanel may further enable quality of service control, such as providingthe ability to test the latency of each connection, and havingprogramming instructions that route specific types of data traffic overspecific connections depending upon the requirements of the datatraffic.

While the invention has been illustrated and described in detail in thedrawings and foregoing description, the same is to be considered asillustrative and not restrictive in character, it being understood thatonly the preferred embodiment has been shown and described and that allchanges and modifications that come within the spirit of the inventionare desired to be protected.

1. A local computer network, comprising: a plurality of local computers;and a router operatively coupled to the local computers and having atleast one connection to a remote computer network for managing at leastone data route between the local computers and the remote computernetwork, wherein the at least one connection of the router to the remotecomputer network includes at least one wireless connection between thelocal computers and the remote computer network that is independent ofthe router.
 2. The local computer network of claim 1, wherein at leastone of the plurality of local computers communicates to the routerinformation regarding one of said at least one wireless connectionsbetween said at least one of the plurality of local computers and theremote computer network.
 3. The local computer network of claim 2,wherein said information comprises an available bandwidth of said onewireless connection.
 4. The local computer network of claim 2, whereinsaid information comprises access parameters of said one wirelessconnection.
 5. The local computer network of claim 1, wherein the routerdetermines an aggregate available bandwidth of a plurality of dataroutes between the local computers and the remote computer network inresponse to having at least two connections to the remote computernetwork.
 6. The local computer network of claim 5, wherein the routerdynamically determines the aggregate available bandwidth as ones of saidplurality of local computers are coupled to and uncoupled from therouter.
 7. The local computer network of claim 5, wherein the routersegregates the aggregate bandwidth into at least two independentbandwidth routes for selective allocation of one of the bandwidth routesto each data exchange between the plurality of local computers and theremote computer network.
 8. The local computer network of claim 7,wherein the at least two independent bandwidth routes include: a wiredbandwidth route including each wired connection between the router andthe remote computer network; and a wireless bandwidth route includingeach connection between the router and the remote computer networkincluding a wireless link.
 9. The local computer network of claim 7,wherein the at least two independent bandwidth routes include: a wiredbandwidth route including each wired connection between the router andthe plurality of computers; and a wireless bandwidth route includingeach wireless connection between the router and the plurality ofcomputers.
 10. The local computer network of claim 7, wherein the atleast two independent bandwidth routes include: a secure bandwidth routefor each secure data exchange between the local computer network and theremote computer network; and an unsecured bandwidth route for eachunsecured data exchange between the local computer network and theremote computer network.
 11. The local computer network of claim 7,wherein the at least two independent bandwidth routes include: a lowlatency bandwidth route for each data exchange of a first type of datapacket between the local computer network and the remote computernetwork; and a high latency bandwidth route for each data exchange of asecond type of data packet between the local computer network and theremote computer network.
 12. The local computer network of claim 1,wherein the router includes a control panel allowing a user to definewhich ones of said plurality of local computers may provide said atleast one connection.
 13. The local computer network of claim 12,wherein said control panel allows said user to connect to a serviceprovider account of said at least one wireless connection to receiveinformation therefrom.
 14. The local computer network of claim 13,wherein said information comprises usage data.
 15. The local computernetwork of claim 13, wherein said information comprises rateinformation.
 16. A method of operating a router for a local computernetwork including a plurality of computers coupled to the router, themethod comprising: operatively coupling the router to the plurality oflocal computers; and connecting the router to a remote computer networkfor managing at least one data route between the local computers and theremote computer network, wherein the connection of the router to theremote computer network includes at least one wireless connectionbetween the plurality of local computers and the remote computer networkthat is independent of the router.
 17. The method of claim 16, furthercomprising: at least one of the plurality of local computerscommunicating to the router information regarding one of said at leastone wireless connections between said at least one of the plurality oflocal computers and the remote computer network.
 18. The method of claim17, wherein said information comprises an available bandwidth of saidone wireless connection.
 19. The method of claim 17, wherein saidinformation comprises access parameters of said one wireless connection.20. The method of claim 16, further comprising: operating the router todetermine an aggregate bandwidth of a plurality of data routes betweenthe local computers and the remote computer network in response tohaving at least two connections to the remote computer network.
 21. Themethod of claim 20, further comprising: operating the router todynamically determine the aggregate available bandwidth as ones of saidplurality of local computers are coupled to and uncoupled from therouter.
 22. The method of claim 20, further comprising: operating therouter to segregate the aggregate bandwidth into at least twoindependent bandwidth routes for selective allocation of one of thebandwidth routes to each data exchange between the plurality of localcomputers and the remote computer network.
 23. The method of claim 22,wherein the at least two independent bandwidth routes include: a wiredbandwidth route including each wired connection between the router andthe remote computer network; and a wireless bandwidth route includingeach wireless connection between the router and the remote computernetwork.
 24. The method of claim 22, wherein the at least twoindependent bandwidth routes include: a wired bandwidth route includingeach wired connection between the router and the plurality of localcomputers; and a wireless bandwidth route for each wireless connectionbetween the router and the plurality of local computers.
 25. The methodof claim 22, wherein the at least two independent bandwidth routesinclude: a secure bandwidth route for each secure data exchange betweenthe local computer network and the remote computer network; and anunsecured bandwidth route for each unsecured data exchange between thelocal computer network and the remote computer network.
 26. The methodof claim 22, wherein the at least two independent bandwidth routesinclude: a low latency bandwidth route for each data exchange of a firsttype of data packet between the local computer network and the remotecomputer network; and a high latency bandwidth route for each dataexchange of a second type of data packet between the local computernetwork and the remote computer network.
 27. The method of claim 16,further comprising: the router displaying a control panel allowing auser to define which ones of said plurality of local computers mayprovide said at least one connection.
 28. The method of claim 27,wherein said control panel allows said user to connect to a serviceprovider account of said at least one wireless connection to receiveinformation therefrom.
 29. The method of claim 28, wherein saidinformation comprises usage data.
 30. The method of claim 28, whereinsaid information comprises rate information.